Technology
Technology
Railway Technology Today 4 (Edited by Kanji Wako)
What Drives Electric Multiple Units?
Hiroshi Hata
Evolution to AC Motors
Direct current (DC) traction motors were
used for a long time after the development
of electric railways. However, since the
1980s, they have been replaced by alternating current (AC) motors, one type of
which commonly used in Japan is inverter
controlled. This article discusses the basic traction systems used in today’s electric multiple units (EMUs) in Japan, with
emphasis on the inverter control system.
the overhead wire converted to DC when
the motor is powered by AC?’ It is because current from the overhead wire is
single phase at a constant voltage and frequency, while the motor current is three
phase with voltages and frequencies that
vary according to speed (explained later);
there is no power converter able to convert voltage and frequency from single to
Figure 1 Main Equipment on Inverter-controlled DC EMU and
Circuit Diagram of Propulsion Circuit
From Current Collection
to Driving
Almost everybody knows that EMUs are
driven by electric motors powered by
current collected through pantographs on
the top of the car. The entire mechanism
can be explained from the viewpoint of
how current flows and drives the motors.
Figure 1 shows a concept of the main
equipment installed on an inverter-controlled EMU and a circuit diagram of the
propulsion circuit. The current collected
by the pantograph is fed to a high-speed
circuit breaker designed to protect the propulsion circuit from ground faults by isolating large fault currents. The current
then passes through a filter reactor to an
inverter where it is converted to AC that
drives the AC traction motors mounted on
the trucks. The motors generate torque
that is transmitted via gear wheels to the
driving wheels. The motor speed is reduced and torque is increased by engaging the gears at ratios of 1:5 to 1:7
(commuter EMUs), to power the wheels.
The above description is for a DC EMU,
but the AC EMU has an additional stepdown transformer to convert the high voltage from the overhead line to a level for
controlling the motors, and an AC to DC
rectifier. In Japan, both the rectifier and
inverter are often housed in a single box
called the main converter (Fig. 2).
A common question is, ‘Why is AC from
40
three phase in one step.
Clearly, it is confusing to use AC and DC,
for the electrification system on one side
and the traction motor on the other and
this requires a clear explanation. Viewed
from the pantograph as the ‘gateway’ to
the EMU, DC was used first in Japan starting at the end of the 19th century. The
AC electrification system was developed
Japan Railway & Transport Review 17 • September 1998
Motors
Filter reactor
Inverter
Motors
(including
capacitor)
Motor
Filter
reactor
Motor
Inverter
Filter
capacitor
Motor
Motor
Figure 2 Location of Transformer and Main Converter on AC EMU
Motors
Transformer
Motors
Main converter
(Rectifier + inverter)
Copyright © 1998 EJRCF. All rights reserved.
Traditional diamond-shaped pantograph
in the 1950s and has been adopted on
various conventional lines (Hokkaido and
Kyushu, etc.) as well as on shinkansen
(JRTR 16, pp. 48 to 58). DC traction motors, which have been in use for a long
time, are being replaced by AC motors.
Types of Pantographs
and Principal Mechanism
The pantograph is an integral part of the
EMU used to collect current from the over-
(JR East)
Single-arm pantograph
head line. It has the following characteristics:
• It must remain in continuous contact
with the overhead wire while the EMU
is running.
• It must not abrade the overhead wire,
and neither must it be subject to excessive wear.
• It must have low aerodynamic resistance.
Japanese railways have long used a diamond-shaped pantograph. It has a re-
(JR East)
placeable contact strip that touches the
overhead wire and is replaced when it
becomes worn by the running abrasion.
This strip must also be able to withstand
arcing current that sometimes occurs between the overhead wire and the contact
strip if the two become separated during
running. The strip is fixed to the base
called the collector shoe, mounted on a
frame.
In Europe, a single-arm pantograph has
been used traditionally and it is being used
increasingly in Japan. A third type of pantograph is called the wing pantograph
which was developed to reduce wind
noise generated by high-speed trains, it is
now used on some of the latest
shinkansen.
From Rheostatic
to Inverter Control
Wing pantograph on JR West Series 500 shinkansen
Copyright © 1998 EJRCF. All rights reserved.
(JR West)
The propulsion system has undergone
considerable change in the history of electric railways. Up until 10 years ago, the
traction motor was DC. For the EMU to
accelerate as it starts, the voltage applied
to the DC motor must be increased as the
EMU picks up speed. This is accomplished by inserting a variable resistor
between the pantograph and motors. The
voltage applied to the motor is controlled
Japan Railway & Transport Review 17 • September 1998
41
Technology
Figure 3
Principle of Rheostatic Control
Pantograph
Traction motors
Variable
resistor
Figure 4 Chopper Control Circuit
Chopper
M
i
i
(a) Chopper on
Chopper
M
i
i
(b) Chopper off
M
M
M
M
M
M
M
M
by varying the resistance. This is called
rheostatic control (Fig. 3). In this system,
the resistance consumes most of the voltage supplied when the EMU is running
slowly and the motor is operating at a low
voltage, presenting various problems,
such as low energy efficiency and a fire
risk if the resistor overheats.
To overcome these problems, chopper
control was developed in the 1970s. As
shown in Fig. 4, instead of a resistor, a
switch is inserted between the pantograph
and motor and the average voltage applied to the motor is varied by changing
the switch on/off time (Fig. 5). On/off
switching must be performed several
hundred times per second, and a semiconductor thyristor is used. In fact, commercialization of the chopper control
system was enabled by development of a
large-capacity thyristor, which also triggered a revolution in EMU control—
replacement of the DC motor by the AC
motor.
The principle of the AC motor is quite
complex and is discussed below, focusing on the differences between AC and
DC motors.
There are several types of AC motors, and
the cage asynchronous motor used widely
in Japan as the traction motor, is described.
Figure 6 shows a DC motor; Figure 7
shows the stator and rotor of an asynchronous motor. The DC motor has a commutator to supply current to the armature
windings during rotation via carbon
brushes. In contrast, the asynchronous
motor uses windings on the stator side to
feed three-phase current. A major feature
is the cage-like construction of the rotor
(Fig. 8), which does not exchange current
with the stator.
What are the major advantages of the
asynchronous motor of this type? They
come from the absence of the commutator and brushes. First, the asynchronous
motor is smaller and lighter. Second, it is
free from the danger of ground faults occurring when the commutator turns at
high speed and supplies a large current
(several hundred amps) to brushes that
may cause sparking to the motor frame or
sparking between brushes. In fact, ground
faults account for the major number of
traction motor failures. Third, brushes
require regular inspection and replacement, and the commutator requires over-
Figure 5 On/Off Chopper Timing Control
Voltage
1,500V
Voltage
1,500V
Time
Low motor speed
42
Japan Railway & Transport Review 17 • September 1998
Voltage
1,500V
Time
Time
High motor speed
Copyright © 1998 EJRCF. All rights reserved.
Figure 6 DC Motor
Figure 7 AC Asynchronous Motor
Stator of asynchronous motor. The stator
is composed of a steel frame covered by
coils inside. The coils are divided into
three blocks: the U, V, and W phases,
forming a rotating field using three-phase
current from the inverter.
(Mitsubishi Electric Co., Ltd.)
Figure 8 Rotor Cage of AC
Asynchronous Motor
Rotor of asynchronous motor. The lack
of commutator allows a larger space for
torque-generating coils.
Bar (Copper)
End ring
(Mitsubishi Electric Co., Ltd.)
haul. Elimination of this work halves
motor maintenance time and costs.
Operating Principles of
Inverter Control System
To understand the inverter control system,
the following three points are important:
• How is torque generated?
• How is the rotating field created by applying three-phase AC to the asynchronous motor?
• How does the inverter create threephase AC from DC with varying frequency and voltage?
These points are explained below.
How is torque generated?
We should start from Fleming’s left- and
right-hand rules (Fig. 9). Fleming’s lefthand rule explains the force applied to a
Copyright © 1998 EJRCF. All rights reserved.
conductor in a magnetic field when current is applied to the conductor. Under
the rule, the direction of the magnetic field
is denoted by the index finger, the direction of current is denoted by the middle
finger and direction of the force applied
to the conductor is denoted by the thumb,
when each is held at 90° to the other. The
strength of the force applied to the conductor is proportional to the product of
the field strength and power of the current.
Fleming’s right-hand rule describes the
direction and strength of voltage generated on the conductor moving through the
magnetic field. When the same three fingers are held at 90° to each other, the index finger denotes the lines of the
magnetic force, the thumb denotes the
motion of the conductor, and the middle
finger denotes the direction of the gener-
ated voltage (positive at finger tip and
negative at base). Again, the level of the
voltage is proportional to the product of
the strength of the field and the velocity
of the conductor.
The torque generation mechanism in the
asynchronous motor is explained below
based on Fleming’s rules.
In the asynchronous motor, a rotating
magnetic field is generated when AC is
applied to the stator windings. Figure 10
demonstrates this point by showing a
magnet turning around the rotor. In relative terms, the magnet is static and the
rotor bars move. Based on the right-hand
rule, this generates voltage at both ends
of each bar. Since the two ends of the bar
are connected to an end ring (conductor),
a current flows through the bar, end ring,
other bar, and opposite end ring. Unlike
the DC motor, this means current flows
Japan Railway & Transport Review 17 • September 1998
43
Technology
Figure 10 Rotating Magnetic Field
Figure 9 Fleming’s Rules
Direction of
force applied
to conductor
Conductor motion
N
Direction of
magnetic field
S
Direction of
magnetic field
S
Generated
voltage
(a) Left-hand rule
in the rotor without the need to supply it
from the stator. Once current is flowing
through the rotor which is in a magnetic
field, based on the left-hand rule, force is
applied to the bars and rotor rotates. In
other words, the motor runs and drives
the EMU.
As the EMU accelerates, the rotor speed
eventually catches up with the rotating
speed of the magnetic field. At this point,
there is no relative motion between the
rotor bar and the rotating magnetic field,
so no voltage is generated and no current
flows, resulting in loss of torque and
meaning that the motor stops when the
above state is reached. To keep the motor (and EMU) running, the speed of the
rotating magnetic field is increased
steadily to keep it above the rotor speed,
thereby maintaining torque. As discussed
later, this is accomplished by raising the
frequency of the AC applied to the motor.
In other words, the motor requires continuous output frequency control using the
inverter.
How is the rotating field created
by applying three-phase AC to
the asynchronous motor?
(b) Right-hand rule
nous motor windings? To understand the
mechanism, the principles of electromagnetism must be explained. Based on the
screw law, the direction of the magnetic
field generated by an electric current is
clockwise to the current direction.
Figure 11 shows the simplified asynchronous motor stator windings, which are
connected alternately at four points.
Figure 12 shows the change in the current flowing in the stator windings, and
the change in the magnetic field generated by the current. There are two points
that look like the north pole of a magnet
where the magnetic flux originates and
two points that look like the south pole
where the magnetic flux ends. Furthermore, these north and south poles appear
to rotate with time. The relationship between the current waveform and the stator shown in the figure indicates that the
shorter the current cycle (or the higher the
frequency), the faster the magnetic field
rotates. In other words, the motor torque
can be maintained at a constant level by
controlling the frequency generated in the
inverter and applied to the motor.
So how is the rotating magnetic field generated by applying AC to the asynchro-
44
Japan Railway & Transport Review 17 • September 1998
N
Direction of
current
How does the inverter convert
DC to three-phase AC with
varying frequency and voltage?
The mechanism for converting DC to AC
using an inverter is explained below.
As shown in Fig. 13, when switches S1
and S4 are ON, and S2 and S3 are OFF,
+E (V) is applied to the motor windings.
On the other hand, when S1 and S4 are
OFF and S2 and S3 are ON, –E (V) is applied. No voltage is applied when all the
switches are off. Each switch can be
turned on or off at any timing. For example, on/off switching at the timing
shown in Fig. 13 (a), produces a voltage
waveform that can be called AC. The
average voltages are shown by the dotted
line. The voltage is decreased by controlling the on/off switching as shown in
(b), and the frequency is increased by
controlling the on/off switching as shown
in (c). For simplicity, the figure illustrates
a single phase, but a three-phase circuit
is actually used. The switches have
evolved first from a thyristor to a smaller
and lighter gate turn-off thyristor (GTO)
that can be turned off without external
voltage, and then to the insulated gate
bipolar transistor (IGBT) capable of highspeed switching. In Japan, this inverter
control system is often called VVVF
Copyright © 1998 EJRCF. All rights reserved.
Figure 13 Inverter Operating Principle (Single Phase)
Inverter
Figure 11 Simplified Stator
Winding
U
S1
S3
U
S2
S4
V
V
S1, S4 ON
All OFF
W
: Average
voltage
S2, S3 ON
All OFF
(a) Voltage between U-V
(b) Voltage between U-V
(at falling voltage)
U
V
(c) Voltage between U-V
(at rising frequency)
W
Winding forward
Winding backward
Figure 12 Generation of Rotating Field by Flowing Three-phase Current
Current
(1)
(2)
(3)
(4)
iu
(5)
(6)
iv
iw
Time
o
S
N
N
N
S
N
SS
N
S
(1)
W
Copyright © 1998 EJRCF. All rights reserved.
N
S
N
N
N
(2)
N
S
S
U V
S
N
S
(3)
Small current winding forward
Big current winding forward
S
S
N
(4)
(5)
(6)
Small current winding backward
Big current winding backward
Japan Railway & Transport Review 17 • September 1998
45
Technology
Figure 14 Synchronous Motor Structure
N
S
Rotor
direction
Field
rotation
direction
S
control, an abbreviation of variable voltage, variable frequency, suggesting the
ability to adjust the three-phase AC voltage and frequency supplied from the inverter to the motor according to the
changing train speed.
Synchronous
and Asynchronous Motors
Another type of AC motor, called the synchronous motor, is in use, especially on
most French TGVs including Thalys, and
Spanish AVEs. Figure 14 shows its struc-
Gate turn-off thyristor (GTO)
46
N
ture. Like the asynchronous motor, the
synchronous motor also has three-phase
AC windings, but the rotor is energized
by DC from an external source to create
magnets. Three-phase current on the stator windings produces a rotating field. The
rotor becomes an electric magnet due to
the DC. Attraction and repulsion between
the field and rotor magnet turn the rotor.
Since the rotor speed is the same as that
of the rotating magnetic field, the motor
is synchronous. Unlike the asynchronous
motor, the synchronous motor requires a
slip ring to supply current to the rotor.
(Mitsubishi Electric Co., Ltd.)
Japan Railway & Transport Review 17 • September 1998
Brushes are used for this purpose and require some maintenance, although it is not
as frequent nor as costly as that required
for DC motors. Why is the synchronous
motor used by TGVs and other rolling
stock? The answer is in the level of technology available when the TGV-A was
designed. Since a large-capacity GTO had
not been developed, supplying voltage to
turn off the thyristor was a major problem. However, the rotor in a synchronous
motor is a magnet so it produces the required voltage between the terminals of
the stator windings. In fact, the voltage is
generated at the exact timing to turn off
the thyristor, eliminating the need for a
turn-off circuit and resulting in reduced
inverter weight. Conversely, the asynchronous motor does not use the above
mechanism and the inverter (at that time)
needed turn-off circuits, which added
weight. In France, the TGV axle weight
was limited to 17 tonnes, and the synchronous motor was the only available choice
meeting this requirement.
Concentrated and
Distributed Traction Systems
Japanese shinkansen use electrical multiple units, sometimes called a distributed
traction system. On the other hand, highspeed railways in Europe mostly use the
concentrated traction system (similar to
Insulated gate bipolar transistor (IGBT)
(Mitsubishi Electric Co., Ltd.)
Copyright © 1998 EJRCF. All rights reserved.
conventional loco-hauled system), where
the train consists of one or two power cars
and several passenger cars. For example,
the Series E2 shinkansen has six powered
passenger cars and two non-powered passenger cars (trailers), while the TGVRéseau has one power car at each end of
eight passenger cars. The TGV-Réseau
power cars carry no passengers.
The relative merits of the two systems are
compared below:
Concentrated traction system
• Relatively small amount of electrical
equipment per train resulting in lower
manufacturing and maintenance costs
• Lower noise and vibration in passenger cars due to physical isolation of passenger cars from power units
Distributed traction system
• Electrical braking on multiple axles resulting in: (a) less maintenance requirements for pneumatic brake parts such
as brake shoes, (b) good braking performance for a variety of performance
conditions, (c) better energy efficiency
through use of regenerative braking
• Reduced maximum axle load, resulting
in: (a) simplified tracks and structures
which reduce maintenance cost, (b)
lowered maximum ground vibration
• Low adhesion coefficient required for
driving axles
• Lower performance loss if propulsion
unit fails in powered car
• High seating capacity
The final choice depends upon which factors are emphasized. In Europe, highspeed trains have traditionally been
hauled by locomotives which have been
superceded by the TGV and ICE. In Japan, the distributed traction system was
selected to reduce maximum axle load
thereby minimizing impact on track and
other structures and reducing construction
costs, as well as to reduce mechanical
braking requirements by using electric
braking on all axles.
A second reason reflects a major difference in railway conditions between Japan
Copyright © 1998 EJRCF. All rights reserved.
and Europe—the braking frequency as a
result of distances between stations. On
the 515-km Tokaido Shinkansen connecting Tokyo and Osaka, originally there
were ten intermediate stations separated
by an average of 47 km (currently there
are 14 intermediate stations). On the other
hand, on the 389-km TGV Southeast Line
between Paris and Lyon, there are only
two intermediate stations where most
TGVs do not stop. Electric brakes offer a
large advantage when braking is frequent.
Overall, European railways selected the
concentrated traction system based on the
initial cost and ride comfort, while the
distributed traction system was selected
in Japan in consideration of the impact
on track and maintenance cost.
With the recent technological advances,
electrical maintenance requirements have
declined, a factor favouring the distributed
traction system. Also, stricter environmental regulation, including public demand
for reduced wayside vibration, serves as
a tail wind for the distributed traction system.
However, there are already high-speed
European trains using the distributed traction system—the Italian ETR450, 460 and
470 , and the future German ICE3. Italy
selected the distributed system to implement pendulum EMUs (pendulum locomotives are not technically feasible at present).
The German ICE3 chose the distributed
system to minimize the required adhesion
coefficient, to increase passenger capacity
and, perhaps more importantly, to lower
the maximum axle load.
Future Challenges
What are the major challenges facing future propulsion systems?
First, development of more compact
lighter on-board equipment is an issue to
pursue. Although the shift from DC to AC
motors has permitted major progress in
these fields, there is still plenty of room
for improvement. Second, energy efficiency is an important challenge. Recent
concern about environmental issues is
prompting railways to step up energy saving efforts, although they already offer a
clear advantage over other transport
modes. In particular, railways are expected to develop hardware and controllers to improve inverter and motor
operating efficiency, while fully leveraging regenerative braking.
On the negative side, inverter control produces high-harmonic noise affecting signalling and communication systems.
Research is required to solve this problem. Some other technical hurdles, including noise reduction and optimized
control for wheel slip remain to be
cleared.
■
Kanji Wako
Mr Kanji Wako is Director in Charge of Research and Development at RTRI. He joined JNR in 1961 after graduating in
engineering from Tohoku University. He is the supervising editor for this series on Railway Technology Today.
Hiroshi Hata
Mr Hata has been Senior Engineer in the Vehicle Technology Development Division of the Railway
Technical Research Institute since 1987. He is engaged in R&D of EMU electric components. He
joined JNR in 1979 after graduating from the Tokyo Institute of Technology.
Japan Railway & Transport Review 17 • September 1998
47
